Method and apparatus for gas cylinder sealing

ABSTRACT

A gasket for a compressed gas cylinder arranged to operate with a gas cylinder having a neck with a top surface around a gas outlet and a side surface extending downwardly from the top surface. The gasket may include an upper portion arranged for positioning on the top surface of the cylinder and for making a seal with the top surface, and a lower portion extending downwardly from the upper portion and around the side surface of the neck of the cylinder, such that the lower portion is arranged to make a seal with the side surface of the gas cylinder. Face and gland seals may be established by the gasket with an opening that receives the gasket and an associated cylinder neck.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.13/569,658 filed Aug. 8, 2012, which is hereby incorporated by referencein its entirety.

BACKGROUND

1. Field of Invention

This disclosure relates gaskets or sealing members for use withcompressed gas canisters, cylinders or containers.

2. Related Art

The coupling of a compressed gas cylinder, canister or other container(herein referred to as a cylinder) with gas delivery mechanisms that usegas supplied by the cylinder often involves an O-ring or other sealelement. Such seal elements are used to help prevent leakage of gas, andare described in U.S. Pat. No. 4,694,850, for example.

SUMMARY

Many commercially available compressed gas cylinders are necessarilyhigh pressured and relatively low volume, and thus any loss of gas inthe process of connecting the cylinder to a gas delivery mechanism isundesirable. One or more embodiments of the invention described hereinprovide for an improved seal between a cylinder and the gas deliverymechanism. The seal may be operable to prevent the initial loss of gasas the cylinder is being opened via a piercing element and furtherprovide a long lasting seal that resists the loss of gas over longperiods of time, such as during storage of the gas delivery mechanism.Also, because a gasket may be mounted on or otherwise coupled to thecylinder and not the gas delivery mechanism, the gasket may be replacedwith a new gasket when a new cylinder is installed, thus eliminating anychance wear due to repeated use.

In accordance with an aspect of the invention, a gasket for a compressedgas cylinder is provided. The gasket may be arranged to operate with agas cylinder having a neck with a top surface around a gas outlet and aside surface extending downwardly from the top surface, e.g., the neckmay have a generally cylindrical shape. The gasket may include an upperportion arranged for positioning on the top surface of the cylinder andfor making a seal with the top surface, and a lower portion extendingdownwardly from the upper portion and around the side surface of theneck of the cylinder, such that the lower portion is arranged to make aseal with the side surface of the gas cylinder.

The upper and lower portions of the gasket may be arranged in differentways, e.g., the lower portion may include a continuous sidewall portion,such as portion having a cylindrical or frustoconical shell shape,arranged to extend around the side surface of the neck of the cylinderand to form a seal with the side surface. In some embodiments, the upperportion and the lower portion may be arranged to form a gas-tight sealwith respective portions of the neck. The upper portion may include anupper opening near a center of the upper portion arranged forpositioning over the gas outlet, e.g., to allow a piercing element tofreely pass to the gas outlet of the cylinder. Alternately, the upperportion may cover the gas outlet, and a piercing element, if used, maypierce the upper portion. The upper portion may make a seal with apiercing element, e.g., a gland or face seal by engaging an outersurface of a piercing element. The upper portion may include a torus orother toroidally-shaped element, e.g., an o-ring shaped portion at theupper portion. The upper portion may include one or more surfacefeatures on a face of the upper surface, e.g., one or more bumps,ridges, grooves, and/or rings.

The lower portion may be attached to, and extend downwardly from, anouter periphery of the upper portion, e.g., the lower portion may extenddownwardly from an outer edge of the upper portion. In some embodiments,the lower portion may have a cylindrical shell shape, e.g., may have asidewall with a wall thickness of about 0.20 inches. Thus, the upper andlower portions may together form a cup-shaped interior space arranged toreceive a part of the neck of the cylinder, e.g., the upper and lowerportions may form a type of cap that fits over the cylinder neck. Thecup-shaped interior space may be tapered to have a smaller size near theupper portion than near a bottom end of the lower portion, e.g., forapplications where the neck has a tapered upper end. The gasket may alsoinclude a ring or other retainer element that extends around a part ofthe lower portion and is arranged to hold the gasket on the neck. Thering may extend only around the lower portion, or may also extend arounda part of the upper portion.

The gasket may be combined with a gas cylinder, e.g., may be permanentlyor removably attached to a neck of the gas cylinder. For example, thegasket may be molded onto the neck of the cylinder, adhered to the neck,welded to the neck, and so on. A gas cylinder receiver may be arrangedwith an opening sized and shaped to receive the gasket and make a sealwith the upper portion and the lower portion of the gasket, e.g., a faceseal with the upper portion and a gland seal with the lower portion. Thereceiver opening may include a piercing element arranged to pierce thegas outlet of a gas cylinder, or a piercing element may be attached tothe gas cylinder or may be an independent part. The receiver opening mayinclude a sidewall with a tapered outer portion and a cylindrical innerportion, e.g., so that the sidewall forms a gland seal with the lowerportion of the gasket when the gasket and neck are introduced into theopening. The receiver opening may also include a bottom surface arrangedto form a face seal with the upper portion of the gasket.

In another aspect of the invention, a method for engaging a gas cylinderwith a gas cylinder receiver (having a receiving opening with a sidewalland a bottom surface) includes providing a gas cylinder with a gasketattached to a neck of the gas cylinder. The neck may have a top surfacearound a gas outlet of the gas cylinder and a side surface extendingdownwardly from the top surface, and the gasket may include portions onthe top surface and side surface of the neck. The neck of the gascylinder may be inserted into the receiving opening of the gas cylinderreceiver such that an upper portion of the gasket on the top surfacemakes a seal (e.g., a face seal) between the top surface of the gascylinder and the bottom surface of the receiver opening, and such that alower portion of the gasket makes a seal (e.g., a gland seal) betweenthe side surface of the gas cylinder and the sidewall of the receivingopening.

In some embodiments, the step of inserting includes sliding the lowerportion of the gasket axially along the sidewall of the receivingopening. In some cases, inserting the neck includes causing the lowerportion to pull the upper portion downwardly relative to the topsurface. For example, friction between the gasket lower portion and thesidewall of the receiver opening may pull the lower portion downwardlyrelative to the cylinder neck, which may cause the top portion to bepulled into contact with the top surface and properly positioned withrespect to the top surface. The receiver opening may be tapered todefine a larger opening at an outer position located farther from thebottom surface than at an inner position located nearer the bottomsurface. A piercing element of the cartridge receiver may pierce the gasoutlet of the gas cylinder, e.g., by passing through a cap positioned atthe gas outlet of the cylinder. Insertion of the neck may also includemaking a seal between the piercing element and the upper portion of theseal, e.g., a conical outer surface of the piercing element may contactan upper opening of the upper portion of the gasket.

In another aspect of the invention, a method for coupling a compressedgas container to a receiving opening of a gas delivery device includesselecting a container having an elongate body and a cylindrical neckdefined by a lower lateral sidewall surface and an upper end faceoriented perpendicular to said lateral wall. At least a portion of boththe lateral sidewall and upper end of the gas cylinder may beencapsulated or otherwise coated with an elastomeric material, e.g., toform a gasket at the top and side surfaces of the neck. A receivingopening may be selected or otherwise provided such that when theencapsulated neck is inserted into the opening, the encapsulated neckinitially forms a gland seal between the lower lateral sidewall and aninterior wall of the opening and such that when the container neck isfully inserted into the opening, the upper end face forms a face sealagainst a bottom surface of the opening. The end face of the cylindermay be pierced with insertion of the neck into the receiver opening, anda release of compressed gas from the container may be minimized, e.g.,by a gland seal at the side surface and/or a face seal at the topsurface of the neck.

The gasket may be arranged to have any suitable features, such as thosediscussed above, including an upper opening and a raised semi-circularring surface with a radius of curvature at an upper portion of thegasket. The gasket and the receiver opening may be arranged to have aface and/or gland seal that is strengthened as the neck is furtheradvanced into the receiver opening, e.g., the upper end face may deformto conform with said bottom surface of the receiver opening therebyforming a stronger seal.

In another illustrative embodiment, a gasket for a neck of a compressedgas cylinder for forming a seal with a receiving opening includes acylindrical sidewall member defining an interior cavity and a loweropening, and an upper portion with an upper opening arrangedperpendicularly to the sidewall member. The interior cavity may betapered adjacent the upper portion in conformity with a distal taperedend of a neck of a gas cylinder and the sidewall member may be operableto form a gland type seal with a sidewall of the receiving opening whilethe upper portion is operable to make a face seal with a bottom surfaceof said opening. In some arrangements, after an initial formation of thegland and face seals, the neck may be advanced further into the openingfor a distance sufficient to puncture the neck by a piercing elementprior to the gasket or other portion preventing further advancement ofthe neck into the opening.

These and other aspects of the invention will be apparent from thefollowing description and claims.

BRIEF DESCRIPTION OF THE DRAWINGS

Aspects of the invention are described below with reference to thefollowing drawings in which like numerals reference like elements, andwherein:

FIG. 1 shows an exploded view of a gas cylinder and gasket in anillustrative embodiment;

FIG. 1 a shows a gasket having a ring-shaped sidewall portion and legsconnecting to an upper portion in an illustrative embodiment;

FIG. 2 a shows a perspective view of a gasket in another embodimenthaving a toroidally-shaped upper portion;

FIG. 2 b shows a side view of the FIG. 2 a embodiment;

FIG. 2 c shows a cross-sectional view of the FIG. 2 a embodiment alongthe line B-B of FIG. 2 b;

FIG. 3 a shows a perspective view of a gasket in another embodimenthaving a flat upper face;

FIG. 3 b shows a side view of the FIG. 3 a embodiment;

FIG. 3 c shows cross-sectional view of the FIG. 3 a embodiment along theline A-A of FIG. 3 b;

FIG. 4 shows a cross-sectional view of a receiving opening of a gasdelivery device and a gas cylinder and gasket to be mated with thereceiving opening;

FIGS. 5 a-5 d depict a sequence of a cylinder and gasket being insertedinto a receiving opening at various stages of insertion depth;

FIG. 5 e shows a fully inserted state of the FIGS. 5 a-5 d embodimentand illustrating deformation of the gasket;

FIGS. 6 a-6 d show various embodiments of gaskets having differentsurface features at a face of the upper portion;

FIGS. 6 e-6 g show various embodiments of gaskets having differentgeometries and material properties in different regions of the gasket;

FIGS. 7 a and 7 b show a side view and a cross-sectional view of anillustrative gas cylinder receiver having a threaded screw-type cylinderadvancement assembly;

FIG. 8 a shows a cross-sectional view of a gasket and cylinderarrangement including a piercing element;

FIGS. 9 a and 9 b show exploded and assembled cross sectional views ofan embodiment including a piercing element with a surface having a ridgeto engage with the face of the gasket;

FIGS. 10 a and 10 b show exploded and assembled cross sectional views ofan embodiment including a piercing element with a ramp arranged near asidewall of the receiver opening to engage with the face of the gasket;

FIGS. 11 a and 11 b show exploded and assembled cross sectional views ofan embodiment including a piercing element with ramps arranged near asidewall of the receiver opening and near a piercing component to engagewith the face of the gasket;

FIGS. 12 a and 12 b show exploded and assembled cross sectional views ofan embodiment including a raised annular ridge extending from an uppersurface of a gasket;

FIGS. 13 a and 13 b show exploded and assembled cross sectional views ofan embodiment including a raised annular ridge at a lateral sidewall ofa gasket;

FIGS. 14 a and 14 b show exploded and assembled cross sectional views ofan embodiment including a ring positioned over a gasket; and

FIGS. 15 a and 15 b shows a side view and cross sectional view of anembodiment including top and bottom rings that sandwich a resilientelement.

DETAILED DESCRIPTION

Various aspects of the invention are described with reference toembodiments of a gasket for interacting with at least a portion of aneck of a gas cylinder, e.g., to provide both a lateral, or side, glandseal and a face seal. Some embodiments are able to provide a gland sealthat allows for axial and/or rotational translation of a cylinder neckwithin a receiving opening while still maintaining a gas-tight seal toprevent or otherwise resist the unwanted release of compressed gas.Maintaining a seal while permitting axial translation may be importantin some applications, e.g., to allow the cylinder neck to be advancedagainst a piercing element that creates an opening in a cap or end pieceat the gas outlet of the cylinder neck as the gas cylinder moves axiallyrelative to the piercing element. As a result, gas leakage may beresisted during the cylinder piercing process, if piercing is used.Further embodiments may provide for a face sealing component of thegasket that provides a face seal with a receiver surface even withmovement of the neck and receiver surface relative to each other,whether in rotation or axial translation. Thus, a face seal may resistgas leakage during cylinder piercing, either alone or in combinationwith a gland seal. It should be understood that various aspects of theinvention may be used alone and/or in any suitable combination with eachother, and thus various embodiments should not be interpreted asrequiring any particular combination or combinations of features.Instead, one or more features of the embodiments described may becombined with any other suitable features of other embodiments. Thus,for example, aspects of the invention may relate to a gasket with a faceseal arrangement that may be used alone, or in combination with a sideor gland seal arrangement, and vice versa.

As noted above, aspects of the invention relate to a gasket for use witha gas cylinder, e.g., a gasket that is arranged to engage with the neckof a cylinder. FIG. 1 is a perspective view of a compressed gas cylinder100 and gasket 200 in an illustrative embodiment. As will be understood,the size, shape, material and/or other characteristics of a gasketarranged to operate with a gas cylinder neck will depend at least inpart on the shape, size, configuration, etc. of the gas cylinder withwhich the gasket is to be used. In the embodiments described herein, gascylinders 100 have a neck 110 of a generally cylindrical shape, i.e.,the neck 110 has a generally flat or beveled top surface 112 surroundinga gas outlet 120 and a cylindrically-shaped side surface 111 extendingdownwardly from the top surface 112. However, aspects of the inventionmay be used with other gas cylinder neck arrangements, such as neckshave a frusto-conically shaped side surface 111, necks having a roundedor pointed top surface 112, and so on. Also although the depictedcylinder 100 is relatively small and designed to be easily portable anddisposable (e.g., having an overall length of about 3.5 inches and adiameter of about 1 inch), aspects of the invention may be used withlarger or smaller and/or differently shaped gas storage containers.Thus, the term gas cylinder as used herein refers generically to acontainer arranged to store and release gas under pressure. Also, inthis embodiment, the neck 110 has a diameter of about 0.375 inches and alength of about 0.5 inches, but other sizes are possible. Moreover,although the neck 110 is shown unthreaded in this embodiment, the neckcan be threaded, unthreaded or have any other surface shape or features(such as a bayonet coupling), e.g., for coupling with a gas cylinderreceiver or other coupling member. The neck 110 in this embodimentincludes a gas outlet 120 that includes a cap or plug that is fitted inan opening of the neck 110 and can be opened via piercing with apiercing element (such as a sharpened or blunt lance) to release gas inthe cylinder through the gas outlet 120. Of course, other arrangementsfor the gas outlet 120 are possible, such as an openable valve, athreaded cap or plug, and so on.

The gas cylinder may be employed with a gas delivery system that usesgas supplied by the cylinder for any suitable purpose. For example,embodiments have been found useful with systems that introduce an inertor otherwise minimally-reactive gas into a wine bottle for dispensingand storing wine as described in U.S. Pat. No. 7,712,637. However, otherapplications are possible, such as tire inflation, beverage carbonation,etc. Exemplary compressed gasses contained in a cylinder may includeair, oxygen, carbon dioxide, argon, neon, helium, nitrogen, and mixturesthereof. Pressure ranges for such cylinders can range from around 1000psi to around 3500 psi, though most commercial cylinders of the size andshape shown in FIG. 1 are at 2600 psi or 3000 psi.

The gasket 200 shown in FIG. 1 is arranged to engage with the neck 110of the cylinder 100 to provide one or more seals with the neck 110 and acylinder receiver opening of a gas delivery system (not shown). Theseal(s) may be a gas-tight seal, e.g., a seal that resists the unwantedleakage or other flow of gas along a surface of the neck 110. Thus, agas-tight seal need not be completely leak-free, but rather suitablyresistant to gas leakage so as to be considered suitable for use inemploying gas provided by the gas cylinder. In this illustrativeembodiment, the gasket 200 has an inverted cup-like shape defined by anupper portion 210 and lower portion 220. The lower portion 220 in thisillustrative embodiment includes a cylindrical sidewall member 230 thatdefines a cup-shaped interior cavity and a lower opening 270 forreceiving the neck 110 of a cylinder. The interior cavity 260 can betapered, contain a fillet, or otherwise shaped to suitably engage theneck 110 of the cylinder 100, e.g., the interior cavity 260 may includea tapered section near the upper portion 210 to receive and conform to atapered portion at the distal end of the neck, i.e., near the topsurface of the cylinder neck. Thus, the gasket 200 may be fitted overthe neck 110 of the cylinder 100 as a sleeve or cover with the lowerportion 220 having a part arranged to sealingly engage with the sidesurface 111 of the neck 110 and/or the upper portion 210 having a partarranged to sealingly engage with the top surface 112 of the neck 110.

The upper portion 210 may have a radially extending portion that definesa face 250 and include an upper opening 280 arranged to be positionedover or adjacent to the gas outlet 120, e.g., to allow gas to flow fromthe outlet 120 without impediment by the gasket 200. The upper opening280 may also be arranged to receive and/or engage with a piercingelement, such as a lance. That is, a piercing element (not shown) maypass through the upper opening 280 without contacting the gasket 200 topierce the gas outlet 120. Alternately, the gasket 200 may contact thepiercing element, e.g., to form a seal with the piercing element, tohelp position the gasket 200 with respect to the piercing element, tohelp guide the piercing element into contact with the gas outlet 120,and so on.

In one aspect of the invention, the gasket is arranged to form a glandor side seal at a side surface 111 of the neck 110 and a face seal witha top surface 112 of the neck 110. This arrangement may make the gasket200 particularly effective in helping to resist gas leakage, e.g.,because the two different seal types may cooperate together to helpresist gas leakage during piercing of the cylinder outlet 120 and/orduring other relative movement of the cylinder 100 and a cylinderreceiver. For example, and as is discussed in more detail below, a partof the lower portion 220 may form a gland or side seal with the neckside surface 111 (as well as with a sidewall of a receiving opening),thus resisting gas leakage even if the lower portion 220 and the sidesurface 111 (or opening sidewall) slide relative to each other. As aresult, a seal may be established and maintained as the neck 110 is slidinto a receiving opening, e.g., to puncture the gas outlet 120, prior tothe face 250 of the upper portion 210 making contact and forming a sealwith the receiving opening. Accordingly, gas released during thepuncture process may be contained and leakage resisted prior to theupper portion 210 forming a seal with the receiving opening and/or thetop surface 112 of the cylinder 100. However, once the neck 110 is fullyreceived into the receiver opening, the upper portion 210 may contactthe receiver opening, and form a face seal with the receiver opening andthe top surface 112 of the gas cylinder.

As is discussed in more detail below, the gasket 200 may be arranged ina variety of different ways to provide characteristics, such as a glandand face seal combination. To provide this combination, the lowerportion 220 and upper portion 210 may be connected together in anysuitable way, e.g., like that shown in FIG. 1 or in otherconfigurations. In an alternative embodiment shown in FIG. 1 a, thegasket 200 has a lower portion 220 that includes a sidewall portion 230having a continuous ring at a lower end that is connected to the upperportion 210 by a plurality of parallel legs. The continuous ring partmay provide a continuous sidewall portion suitable to provide a glandseal with the side surface 111 at a radially inner side and with areceiver opening at a radially outer side of the sidewall portion. Thelegs may help maintain the ring part and the upper portion 210 in adesired position on the neck 110 and relative to each other. Forexample, and as described in more detail below, insertion of the neck110/gasket 200 combination in to a receiving opening of a gas deliverydevice may tend to pull the lower portion 220 downwardly along the sidesurface 111 of the neck 110 (e.g., because of friction with thereceiving opening sidewall). By having the lower portion 220 connectedto the upper portion 210, the lower portion 210 (such as the ring) maybe maintained in a desired location on the neck and/or the upper portion210 may be drawn downwardly and into contact with the top surface 112 ofthe neck, helping to position the upper portion 210 to establish a seal.Of course, the arrangement of FIG. 1 a is only one example, and thelower portion 220 could be arranged in different ways, e.g., thestraight legs could be replaced with resilient elements to provide aresilient bias to urge the lower portion 220 and upper portion 210together in the presence of a force that draws the two components apart,replaced with a web or mesh component, or with “X” shaped bars, etc.

The upper and lower portions of the gasket may be configured indifferent ways to provide a gland seal at the side surface and a faceseal at the top surface of the cylinder neck. FIGS. 2 a-2 c showperspective, side and cross-sectional views of another illustrativegasket 200 in accordance with aspects of the invention. In thisembodiment, the upper portion 210 includes a torus- or othertoroidally-shaped portion that defines the upper opening 280 and theupper face 250. Thus, the upper face 250 may be curved surface much likea standard o-ring shape. In this embodiment, the gasket 200 is arrangedto operate with a gas cylinder neck 110 like that of FIG. 1, e.g.,having a diameter of about 0.375 inches, a length of about 0.5 inches, aslight taper or bevel at the upper part of the side surface 111 near thetop surface of about 8-10 degrees, and a beveled top surface 112 formingan angle of about 110-120 degrees with the side surface 111. The gasket200 has a large diameter D of about 0.246 inches, and the radius R ofthe torus-shaped portion is about 0.085 inches, but other values, from0.00 inches to 0.5 inches are possible, as are flat surfaces finishedwith beveled edges. The gasket may have an outer diameter OD of about0.375 inches, with the diameter ID of the lower opening 270 being about0.335 inches, e.g., requiring the gasket to be stretched to fit over theneck 110 of the cylinder 100. The gasket 200 may have a total height ofabout 0.43 inches, with the upper portion 210 having a height h of about0.104 inches, A lower part of the lower portion 220 may have a constantthickness t of about 0.020 inches up to a height a (about 0.22 inches),at which point the inner wall of the lower portion 220 may taperinwardly, increasing the wall thickness of the lower portion 220 in thisupper area. The tapered portion may be arranged at an angle of about8-10 degrees relative to the lower part extending from the lower end tothe height a and may have an approximate length b of about 0.06 inches.The upper part of the tapered portion may transition to the torus-shapedsection by a fillet or curved section 261 having a radius Rc of about0.05 inches.

FIGS. 3 a-c depict another embodiment that incorporates one or moreaspects of the invention. Here, the gasket 200 is arranged similarly tothat in FIGS. 2 a-2 c and includes an upper portion 210 having a moreflat upper face surface 250 and inner surface compared to the roundedsurface defined by the torus-shaped portion shown in FIGS. 2 a-c. Thedimensions a, H and Rc are similar to that in the FIGS. 2 a-2 cembodiment, but the height h in this embodiment is about 0.115 inches,and the distance b is about 0.01 inches. Note that the angle α of thetapered section may be about 8-10 degrees, e.g., to match or suitablyconform to a taper on the side surface 111 of the neck 110. Also, theupper portion 210 is radiused at its upper, outer periphery with a curvehaving a radius Ro of about 0.02 inches, and defines the upper opening280 to have a diameter d of about 0.125 inches. The face 250 need not beflat, however, and may be beveled or curved at its outer edge and/or atthe opening 280.

The specified dimensions above are given for illustrative purposes andnot to be construed as limiting, and it should be understood thatvarious thicknesses could be used to cooperate with a variety of neckgeometries and coupling members or receiving opening geometries. Also,the upper opening 280 could be omitted entirely (e.g., where a piercingelement pierces the gasket 200) or otherwise changed in size.

Gaskets in accordance with aspects of the invention may be made of, orotherwise include, an elastomeric material such as a polymer, elastomer,rubber, or composite thereof. Exemplary materials include natural rubberand thermoplastic elastomers and more specifically santoprene, neoprene,silicone, urethane, and butyl rubber. The durometer of the material maybe 70-95, but values between 50 and 100 on the shore A scale can besuitable for applications. Those of skill will appreciate that a choiceof durometer may require adjustment to component size, shape or otherfeatures, such as requiring thicker or thinner components to providedesired sealing strength, a suitable insertion force to engage thecylinder neck/gasket with a receiving opening, etc. As discussed morebelow, the gasket may include zones of differing durometer and/ormaterial, such as an outer sidewall or sheath having a greater valuehardness, stiffness, resilience, etc., than an upper face.

The gaskets disclosed herein are intended for use with threaded and/orunthreaded necks of various containers, and a variety of methods mayemployed to engage and/or seal gaskets thereto. For example, gaskets maybe threaded onto a threaded neck of a cylinder or stretched over athreaded or unthreaded neck, e.g., relying on friction to maintainengagement of the gasket with the cylinder neck. Alternatively, a gasketmay be shrink fit, heated, bonded, welded, cross linked, adhered with anadhesive, chemically altered, or transformed to engage a gasket with theneck of the cylinder. Such engagement may form a seal between the gasketand the cylinder, whether a gland seal at the side surface 111 and/or aface seal at the top surface 112, or a seal (such as a gas-tight seal)may be formed by pressure or other force that presses the gasket intosuitable contact with the neck. The seal-forming force may be providedwhen the cylinder/gasket are engaged with a cylinder receiver.

As mentioned above, aspects of the invention relate to gas cylinderengagement with different types of gas cylinder receivers, includingthose that threadedly engage with a gas cylinder, those that receive agas cylinder that is slid axially into a receiver opening and others.For example, U.S. Pat. No. 4,867,209; U.S. Pat. No. 5,020,395; U.S. Pat.No. 5,163,909 describe different cylinder engagement arrangements andare hereby incorporated by reference with respect to their teachingsregarding mechanisms for engaging a gas cylinder with a cylinderreceiver.

FIG. 4 shows a partial, cross-sectional view of a cylinder receiver 10that may be part of a gas delivery mechanism or system in a device thatuses gas supplied by a cylinder, and may include elements such as aregulator to control a pressure of gas provided, a piercing element topierce the gas outlet of a cylinder, a valve, spout, nozzle, or hose tocontrol and deliver gas to a desired location, such as a wine bottle,bicycle tire, beverage carbonator, etc. The cylinder receiver 10includes a receiver opening 300 that is arranged to engage with at leasta portion of a gas cylinder neck 110 having an attached gasket 200. Inthis example, the receiver opening 300 is arranged as a bore or hole 300that is sized and shaped to receive a gasketed cylinder neck that isaxially slid into the hole 300, although other arrangements are possiblefor the receiver opening 300. For example, the receiver opening 300 mayinclude a clamp arranged so that the neck 110 is received into theopening 300 without resistance and that clamps onto the gasket/neck ofthe cylinder 100. In another arrangement, the opening may include athreaded element that engages with the cylinder itself or a carrier orholder that holds the cylinder and engages the neck with the opening 300by threading onto the cylinder receiver 10. In short, a variety ofdifferent receiver opening arrangements are possible.

In this illustrative embodiment, while the hole 300 may be uniform inshape, such as a cylindrically-shaped hole with uniform walls, the hole300 may have a stepped diameter (with one or more smaller diameterslocated at inner portions of the hole, contain a taper, have a chamferor other arrangement. As shown in FIG. 4, the hole 300 contains an innersection 320 which is straight or untapered and an outer tapered orchamfered section 310 with the wall(s) of the outer section 310 arrangedat an offset angle of about 5-30 degrees relative to the inner section320. The inner section 320 is adjacent to a bottom surface 340 of thehole 300, which in this embodiment is arranged as a circular, planarsurface, but may have any suitable surface features. The bottom surface340 also carries a piercing element 400 for opening a cylinder, althoughother arrangements are possible, such as having the piercing element 400extend through an opening in the bottom surface 340, or having thepiercing element carried on the gas cylinder. Of course, in somearrangements, no piercing element may be needed at all, such as those inwhich the gas cylinder includes a valve.

In this illustrative embodiment, the receiver opening 300 is arranged tooperate with a gasket and cylinder configured as in FIGS. 3 a-3 c. Thus,the opening 300 may have a total depth of about 0.22 inches, alength/depth of the outer tapered section 310 of about 0.122 inches, adiameter of the inner section 320 of about 0.375 inches, and an angle ofthe tapered section of about 7.5 degrees relative to the straightwall(s) of the inner section 320. The taper of the outer section 310defines the size of the opening at the outermost portion of the outersection 310 to be larger than the maximum diameter of the gasket200/neck 110, allowing the gasket 200 to be introduced into the opening300 relatively easily and without resistance. However, as the gasket 200and neck 110 are pushed axially into the opening 300, the size of theopening 300 decreases, and the gasket 200 is squeezed between theopening 300 and the neck 110. As a result, the lower portion 220 of thegasket 200 forms a gland or side seal with the sidewalls of the opening300, particularly at the breakpoint where the outer section 310 meetsthe inner section 320, and with the side surface 111 of the neck 110. Asused herein, a gland or side seal is a seal formed between a part of thelower portion 220 of the gasket and the side surface of the neck 110 ofa cylinder and/or between a part of the lower portion 220 and acorresponding portion of a receiver opening 300, and may involve slidingmotion between the gasket 200 and the side surface 111 and/or betweenthe gasket 200 and the sidewall of the opening 300, although such motionis not required. With advancement of the neck 110 into the opening 300,the piercing element 400 may penetrate the gas outlet 120, e.g.,piercing a cap or cover at the outlet. This piercing releases gas fromthe cylinder, but the gland seal may resist gas leakage along the neck110 and/or the opening 300 sidewall. Further advancement may bring theface 250 of the upper portion 210 of the gasket 200 into contact withthe bottom surface 340, causing the gasket 200 to form a face seal withthe bottom surface 340 and with the top surface 112 of the cylinder 100.In other embodiments, the upper portion 210 may contact the bottomsurface 340 prior to axial movement of the cylinder neck 110 beingcomplete, and thus a face seal may be formed prior to, or during,piercing of the gas outlet 120. A face seal is a seal formed between theupper portion 210 of the gasket and the top surface 112 of the cylinder100 or between the upper portion 210 and the bottom surface 340. A faceseal typically will not be created in an area where sliding motion ispresent between the gasket and the top surface 112 or bottom surface340.

FIGS. 5 a-5 d illustrate an exemplary advancement sequence involving agasketed compressed gas cylinder as described in one or more embodimentsherein being inserted into the chamfered opening of a receiver of a gasdelivery mechanism. At various stages certain seals will be made as thecylinder is advanced until the gas outlet of the cylinder has beenpunctured or otherwise opened and until the friction and hardening ofthe gasket, or other mechanical interference, prevents further axialtravel of the cylinder into the opening.

In FIG. 5 a, the neck 110 of the cylinder 100 is being advanced axiallyinto the opening 300 of a cylinder receiver 10. At this stage and inthis illustrative embodiment, the gasket 200 is neither compressed nordeformed, at least from any force outside of the gasket. However, asnoted above, the gasket 200 may be stretched or otherwise deformed whenengaged with the neck 110 of the cylinder. In this embodiment, the neck110 of the cylinder is threaded, and the gasket 200 may be threaded ontothe neck 110 (whether or not the gasket has corresponding internalthreads), pressed over the neck 110, adhered to the neck by an adhesivematerial, placed over the neck without deformation of the gasket 200, orotherwise engaged with the neck. The architecture of the opening 300 isidentical to that in FIG. 4 with the exception that a base 410 of thepiercing element 300 is shown and includes an indentation or ridgefeature in the bottom surface 340 of the opening 300.

Upon initial insertion of the gasket 200 into the proximal chamferedsection 310 of the opening 300 as shown in FIG. 5 b, the upper section210 of the gasket 200 deforms inwardly and/or axially, forming aninitial radial gland seal between the gasket sidewall 230 and theopening sidewall and/or the cylinder side surface 111. In FIG. 5 c, thecylinder and gasket have been further advanced so that now a face sealforms between the bottom surface 340 and piercing element base 410 andthe upper face 250 of the gasket 200. The gasket is deformed axiallyabove and below the threads on the neck 110 and radially about thethreads and upper opening 280, e.g., to form a gland seal with the sidesurface 111 of the neck 110. The radial gland seal between the sidewall230 of the gasket 200 has now formed in both outer 310 and inner 320portions of the opening 300. At this point, a fairly strong seal (in theform of a face and gland seal) has been created in preparation for thepiercing element 400 to pierce the gas outlet 120 of the cylinder andrelease the gas held under pressure, e.g., at 2600 psi. Note that thecurved profile of the upper portion 210 of the gasket and the void inthe upper opening 280 provide space for the gasket to deform into orflatten into and thus permit further axial travel into the opening 300.Finally, FIG. 5 d shows the neck fully advanced within the opening 300and the piercing element 400 having pierced, punctured or otherwiseopened the cylinder. The upper portion 210 has been deformed from arounded o-ring-like structure to conform with the bottom surface 340 andthe piercing element base 410 of the opening 300, thus making a strongface seal. The features (steps, ridges, recesses, flange) in the bottomsurface 340 and base 410 are operable to capture, bind, or impede thetendency of the gasket to creep or splay out laterally or axially downthe neck, but are not necessarily required. Shown also is a gland sealbetween the piercing element 400 and the upper opening 280, though insome instances this seal does not form. Also, at this stage ofinsertion, or just prior to it, gasket material may have undergone“creep” or otherwise been forced by the pressurized contents axiallydown the sidewall 230. However, at the point of advancement when theintersection of the outer portion 310 and inner portion 320 portion ofthe opening 300 coincides with a tapered end 111 of the neck 110, abinding point or equilibrium between the neck and the bore is createdwherein the gasket material no longer deforms or creeps in either axialdirection, but compresses and prevents further axial travel of the neck.FIG. 5 e illustrates the deformation and compression that the gasket hasundergone with a dotted line 240 indicating its initial shape prior toinsertion and undergoing stress, and the solid line indicating that thegasket has largely conformed to the shape of the opening 300.

In addition to the previous gasket embodiments described, othervariations may be more suited for particular applications and cylinderreceiver geometries and arrangements. For example, FIGS. 6 a-6 d showgaskets 200 with largely featureless sidewalls 230, but having one ormore rings (FIG. 6 a), dimples (FIG. 6 b), ridges or slots (FIG. 6 c),and raised bumps (FIG. 6 d) presented on the face 250 of the upperportion 210 of the gasket 250. Alternatively, or in addition, suchfeatures may be presented on the sidewalls 230. These features may beoperable to deform and allow axial travel while still providing a sealand also to bind to features carried in the bottom surface 340 of anopening 300 of a cylinder receiver 10, such as ridges, steps,indentations and the like, to prevent creep and splaying of the gasket.

As mentioned above, a gasket may be arranged to have different materialsand/or properties in different portions of the gasket. For example,FIGS. 6 e-6 g show cross-sectional views of gaskets with selected zonesof different elasticity, hardness, and/or durometer. In FIG. 6 e, thezones are the upper and lower portions 210, 220 of the gasket 200, e.g.,the upper portion 210 may have a lower elasticity, hardness or durometerthan the lower portion 220, or vice versa. In FIG. 6 f, the zones ofdifferent material/characteristic are the entire lower portion 220 and apart of the gasket at the outer periphery extending into the upperportion 210 and a radially inner part of the upper portion 210 includingan inner part of the face 250 of the gasket 200. Again, these differentzones may have a different hardness, elasticity or durometer than eachother, and these features may be provided by different materials,treatments (such as thermal or chemical treatments), etc. In FIG. 6 gthe zones of different material/characteristic are an exterior portiondefining the outer surface 211 of the gasket 200 and an interior portion212 of the gasket 200 intended to contact the side surface 111 and topsurface 112 of the neck 110 of a cylinder. The differing zones in theabove gaskets may be created through treating or processing a unitarymaterial differently according to the desired properties of each zone orby fashioning the gasket as a composite of more than one material.

While various cylinder receivers are generally described above, FIGS. 7a and 7 show a side and cross sectional view of a cylinder receiver 10in an illustrative embodiment. As mentioned above, aspects of theinvention may be employed with any suitable cylinder receiver 10 for anygas delivery device, and so the illustrative embodiment of FIGS. 7 a and7 b should not be construed as limiting. In this embodiment, thecylinder receiver 10 includes a hollow cup body 500 with a threaded end520 for coupling with a receiver body 505 and a bearing surface 510located in the base of the cup body 500. The cup body 500 is arranged toreceive the cylinder 100 so that the bearing surface 510 supports thecylinder 100 in the cup body 500. The bearing surface 510 is preferablenarrow (but not able to puncture the cylinder) and/or lubricious and isoperable not to impart rotational force to the cylinder as the cup body500 is threaded onto the receiver body 505. As will be appreciated,threading the cup body 500 onto the receiver body 505 advances the neck110 of the cylinder 100 axially into engagement with the receiveropening 300 and piercing element 400 so that a suitable seal is made andthe gas outlet 120 of the cylinder is opened. In this embodiment, thecylinder 100 does not move rotationally while engaging with the opening300, but such motion is possible, e.g., where a threaded neck of thecylinder threadedly engages with the opening 300.

Although some embodiments described above have a gasket and cylinderarranged to operate with a piercing element that is carried by acylinder receiver, a piercing element (if required) may be carried onthe cylinder. For example, FIG. 8 a shows an alternative embodiment thatincludes a piercing element 400 and a gasket 200 in combination with acylinder 100. In this example, a smooth necked cylinder (which couldalternatively be threaded) is fitted with a gasket 200 as describedelsewhere herein and that helps hold a piercing element 400 in placerelative to the gas outlet 120. Thus, the piercing element 400 can becarried by the gasket 200, although it is also possible that thepiercing element 400 could be separate from the gasket, e.g., attachedto the cylinder 100. In this embodiment, the piercing element 400includes a metal flange (not shown) that extends against and/or under aportion of the upper portion 210 of the gasket 200 and a sharpenedarcuate member that extends above the gas outlet 120. In use, a bluntanvil or other component of the receiver engages the piercing element400 and forces it through the gas outlet 120 while a face and gland sealare provided by the gasket. Of course, the piercing element 400 could bearranged in other ways, e.g., to have a configuration like that shown inFIG. 5 e.

Aspects of the invention also relate to configurations for a cylinderreceiver, including arrangements for the receiver opening. For example,FIGS. 9 a and 9 b depict an embodiment of a cylinder 100 and gasket 200that is arranged similarly to that shown in FIGS. 2 a-2 c and 3 a-3 c.Also, a cylinder receiver 10 is shown that is arranged similarly to thatin FIGS. 5 a-5 e. However, in this embodiment, the cylinder receiver 10includes an opening 300 that receives a piercing element 400 that alsoforms the bottom surface 340 of the opening when the piercing element400 is received into the opening 300. This embodiment, at least in part,acts to improve the likelihood of establishing, or the robustness of, aface seal between piercing element 400 and the gasket 200 during theprocess of engaging the cylinder 100 with the cylinder receiver 10. Inthis embodiment, gasket 200 is bonded or otherwise attached to thecylinder 100 at the neck 110, and the piercing element base 410 issealingly engaged with the opening 300 in the position shown in FIG. 9b, e.g., by welding, adhesive, a threaded engagement, friction fit, etc.

As the neck 110 and gasket 200 are introduced into the opening 300, thepiercing element 400 contacts and begins to pierce the gas outlet 120,and the upper face of the gasket 250 makes contact with a raised annularring or ridge 430 on the piercing element base 410 at the bottom surface340 of the opening 300. (While in this embodiment the ring or ridge isformed on the piercing element base 410, the ring or ridge could beformed on the body of the receiver 10.) This early contact helps tocreate an early face seal during or prior to piercing of gas outlet 120as shown in FIG. 9 b. As cylinder 100 is advanced further into opening300, the gasket 200, which is compressible in this embodiment, is ableto deform around the ring or ridge 430 at the bottom surface 340,improving the face seal and increasing the extent of rupture of the gasoutlet 120 by the piercing element 400. A gland seal may, or may not, beprovided by the lower portion 220 of the gasket 200 with the neck 110and/or the sidewall of the opening 300. The ring or ridge in thisembodiment is shown as a simple raised portion with a semi-circularcross section. Alternatively, the ring or ridge 430 could be, orinclude, a sharpened fin or triangular wedge to increase pressure on theface 250 of the gasket 200. In addition, a multitude of ridges could beemployed, e.g., in concentric form. Face 250 of gasket 200 is shown asessentially flat relative to ridge 430. Alternatively, the face 250could include rounded or annular ridges of its own, potentiallyproviding a mating surface or surfaces with the ring or ridge 430.

FIGS. 10 a and 10 b depict an alternative embodiment of a piercingelement 400/bottom surface 340 arranged to engage with a gasket 200. Inthis embodiment, the bottom surface 340 of the opening 300 includes anouter annular ramp 450 on the gasket-facing surface of the piercingelement base 410 which acts to create a gland or radial compression sealbetween upper opening 280 of the gasket 200 and the piercing element 400as the gasket 200 is advanced into the opening 300. In this embodiment,such a radial or gland seal may be formed during and/or after punctureof the gas outlet 120 by the piercing element 400. This radial seal maybe additive to the face seal created between gasket 200 and the flatportion of the bottom surface 340 which occurs at full insertion ofcylinder neck 110 and gasket 200 into the opening 300. The location ofthe ramp 450 may also act to improve the seal between gasket 200 and thecylinder neck 110 as ramp 450 wedges the gasket 200 against the neck110. In this embodiment, the diameter of upper opening 280 is closelymatched to the diameter of the piercing element 400 to generate a glandseal soon after contact with ramp 450, although such a seal need not bemade. Thus, the upper opening 280 in this and other embodiments may besmaller than, equal to, or larger than an outer diameter of the piercingelement 400, depending upon the desired amount of gland seal, given themating surfaces of the gasket, piercing element and receiver opening.Ramp 450 is shown to be part of the piercing element base 410, butalternatively could be integral to the receiver body. Also, ramp 450 isshown as a simple ramped or chamfered surface, but could alternativelybe a simple stepped geometry, employ a parabolic ramp, or other varyingramp surface.

FIGS. 11 a and 11 b depict another alternative embodiment for arranginga bottom surface 340 of a receiver opening 300. Again, the surfacefeatures defining the bottom surface 340 are arranged on a base 410 of apiercing element 400, but could be arranged on the receiver body, or acombination of a receiver body and a piercing element or othercomponent. In this embodiment, an additional ramp 400′ is provided inaddition to a ramp 450 like that in FIGS. 10 a and 10 b. Thisarrangement provides an annular cavity at the bottom surface 340 andenables improved gland sealing between the gasket 200, the base 410 andthe piercing element 400. As gasket 200 is advanced into the narrowingregion formed between ramp 450 and the ramp 400′, the gasket 200 iscompressed radially, improving the gland seal. Ramp 450 and the ramp400′ are shown to contact gasket 200 at a same point of advancement ofcylinder neck 110 into opening 300, but alternatively, the outer ramp450 could be longer, i.e. could contact gasket 200 earlier than theinner ramp 400′, or visa-versa. Again, ramp 450 and/or 400′ couldalternatively be formed in the opening 300 while achieving the samegoal.

FIGS. 12 a and 12 b depict yet another alternative embodiment for agasket 200 that acts to improve a face seal between the face 250 and thebottom surface 340 of the receiver opening 300. In this embodiment,gasket face 250 has a raised annular ridge 250′ positioned at or nearthe outer periphery of the gasket 200. This raised ridge 250′ forms acup-shaped or bowl-shaped depression in the face 250 and makes contactwith the bottom surface 340 prior to opening of the gas outlet 120 bythe piercing element 400. As cylinder 100 is advanced into the opening300, the ridge 250′ is compressed against surface 340, creating a faceseal as shown in FIG. 12 b. As the cylinder is advanced further, ridge250′ compresses further, ultimately allowing contact between theremainder of the face 250 with the bottom surface 340. Ridge 250′ isbiased toward the outer periphery of the gasket 200 to take advantage ofpressure released from the cylinder 100 following piercing by thepiercing element 400 to create a gland seal as the pressure forces theridge 250′ outwardly against the sidewall of the opening 300. However,in alternate embodiments, such a gasket-face ridge could be biasedtoward an inner portion of the opening 300 or may be located anywherealong the gasket face 250. Again, the lower portion 220 of the gasket200 may, or may not, provide a gland seal. The ridge is shown as aradiused projection from face 250, but could be effective in a varietyof different shapes and cross sections. In addition, bottom surface 340is shown as flat, but could alternatively employ ramps or ridges as inthe embodiments depicted in FIGS. 9-11, or alternatively employ matingrelieves into bottom surface 340.

FIGS. 13 a and 13 b depict an alternative embodiment of gasket 200employing a feature 231 on the outer surface of the lateral sidewall 230of the gasket 200. This feature creates an improved gland seal betweenthe feature 231 and the sidewall surface 320 of the opening 300 prior topuncture of the gas outlet 120 by the piercing element 400. In thisembodiment, feature 231 is a simple raised annular ridge or ring aboutthe circumference of gasket lateral sidewall 230, and has an outerdiameter that is greater than the inner diameter of opening 300 asdefined by the sidewall surface 320. Hence, once feature 231 enters theregion of the opening encompassed by the sidewall surface 320, a glandseal is created between surface 320 and the gasket 200 in the region ofthe feature 231. This seal is preferably formed prior to puncture of thegas outlet 120 by the piercing element 400. As cylinder 100 is advancedfurther into the opening 300, a face seal may be additionally createdbetween gasket 200 and the bottom surface 340, though may not berequired. While only one feature 231 is shown in this embodiment, therecould be multiple features of varying size and/or geometry located atvarious points along gasket lateral sidewall 230 to optimize the extentof a gland seal formed during various stages of insertion of cylinderneck 110 into bore 300. Moreover, such features 231 may be provided onthe inner surface of the lower portion 220 of the gasket 200 forinteraction with the cylinder neck side surface 111.

FIGS. 14 a and 14 b depict another embodiment that includes a ring 600for securing the gasket 200 to a cylinder neck 110. As discussed above,a gasket 200 may be permanently attached to a cylinder, or not, and maybe attached in a variety of different ways. In this embodiment, the ring600 is secured over a part of the gasket lateral sidewall 230,compressing the lateral sidewall 230 portion against the cylinder neck110. In some embodiments, the amount of compression is great enough tocreate a gland seal between the gasket lower portion 220 and thecylinder neck 110 sufficient to resist a peak filling pressure ofcylinder 100, e.g., 2600 psi. However, in other embodiments, the ring600 may fit relatively loosely over the gasket 200. In FIG. 14 b, thering 600 is shown compressing lateral wall 230 against the cylinder neck110, however, a portion of the ring 600 extends above both the neck 110and the top surface of the neck 110. Such an extension can supportportions of the gasket 200 above the top surface 112 against extrudingthrough any gap between cylinder neck 110 and the wall of opening 300.In a preferred use, the outer diameter of the ring 600 would be closeto, but smaller than the diameter of the opening 300 of a receiver 10,with a “slip-fit” being optimal. However, in other arrangements, theouter diameter of the ring 600 may be larger than the opening 300 (or atleast a portion of the opening 300 with which the ring 600 engages) sothat the ring 600 is clamped onto the gasket 200 and the neck 110. Thismay help create a gland seal between the gasket 200 and the neck 110and/or the ring 600. In this embodiment, the ring 600 is shown as aseparate piece that is assembled over gasket 200 and neck 110.Alternatively, the ring 600 could be molded within the gasket 200, e.g.,as part of the lateral sidewall 230 of the lower portion 220. The ring600 in some embodiments is preferably made from a material highlyresistant to hoop stress or tensional forces, and could be entirelyrigid or flexible, at least in part. Also, while the ring 600 is shownas a single, unitary body, the ring 600 could include multiple smallerrings that are adjacent each other, or spaced apart at any suitabledistance along the length of the gasket 200. In another arrangement, thering 600 could be formed from a tightly wound string, wire, strand orcable that is wrapped either once or multiple times around the gasket200.

The embodiment of FIGS. 14 a and 14 b depict one illustrative embodimentof a mechanical interlock between the gasket 200 and the cylinder 100,and it should be understood that other arrangements are possible. Suchan interlock could alternatively be achieved by threading of theinternal surface of lower portion 220 that engages with threading ofcylinder neck 110. Alternatively or in addition, the gasket 200 could beglued, ultrasonically welded to, or insert molded about the neck 110 ofthe cylinder 100. In the depicted embodiments, the gasket 200 is showncovering portions of the cylinder neck and at least a portion of the topsurface of the cylinder neck. Alternatively, the gasket 200 could coverthe entirety of the outer surface of cylinder 100, or portions thereof.

FIGS. 15 a and 15 b depict a further embodiment of a gasket assemblyoperable to provide a gland seal with a side wall of a gas cylinderreceiver. In this embodiment, the gasket includes a top sleeve 201, abottom sleeve 202, and a resilient element 203 positioned between thetop and bottom sleeves 201, 202. The bottom sleeve 202, resilientelement 203 and a part of the top sleeve 201 form a lower portion 220 ofthe gasket 200, and an upper part of the top sleeve 201 forms an upperportion 210 of the gasket 200. The top and bottom sleeves 201, 202 areconfigured to form a groove or seat in which the resilient element 203may be carried and so that the top and bottom sleeves 201, 202 can exerta force on the resilient element 203 that causes the resilient element203 to expand radially outward and/or inward. In this embodiment, thetop and bottom sleeves 201, 202 are arranged to be capable of movementtoward each other so that the resilient element 203 is squeezed betweenthe top and bottom sleeves 201, 202, i.e., the top and bottom sleeves201, 202 may exert an axial force on top and bottom surfaces of theresilient element 203. This axial force may cause the resilient elementto expand radially inwardly and/or outwardly. Outward and/or inwardradial movement of the resilient element 203 may cause the resilientelement to form a gland seal with a sidewall of a gas cylinder receiveropening and/or with a portion of the sleeves 201, 202 or the sidesurface 111 of the neck 110.

While in this embodiment the top and bottom sleeves 201, 202 arearranged to be concentric and slidably coupled to each other to allowfor axial translation relative to each other, such an arrangement is notnecessary. For example, the top and bottom sleeves 201, 202 may have asimple cylindrical shell shape and be positioned on upper and lowersides, respectively, of the resilient element 203. Also, while in thisembodiment the top and bottom sleeves 201, 202 are interlocked so thatmovement of the sleeves 201, 202 away from each other is limited (e.g.,a hook 201 a at a lower end of the top sleeve 201 may engage a hook 202a of the bottom sleeve 202 to prevent removal of the top sleeve 201),such an arrangement is not necessary. Instead, the sleeves 201, 202 maybe made easily separable, if desired, e.g., so that the top sleeve 201can be removed from the gasket 200. Also, the hooks 201 a, 202 a may bebeveled, e.g., to help allow insertion of the hook 201 a into a spacedefined by the bottom sleeve 202 below the hook 202 a.

While in this embodiment, radial movement of the resilient element 203is caused by applying an axial force to the resilient element 203, thegasket 200 may be arranged to apply a radial force to the resilientelement 203, or a force that includes radial and axial components. Forexample, surfaces of the top and bottom sleeves 201, 202 that engage theresilient element 203 at the groove may be beveled so that as thesleeves 201, 202 are moved toward each other, the bevels push theresilient element 203 radially outwardly. In another embodiment, thesleeves 201, 202 may each have tapered portions that engage each otherso that the groove in which the resilient element 203 sits expandsradially outwardly. For example, the top sleeve 201 may have afrusto-conically tapered lower end that is received inside of an upperend of the bottom sleeve 202. Insertion of the tapered lower end of thetop sleeve 201, 202 may cause the upper end of the bottom sleeve 202 toexpand radially outwardly (whether through elastic and/or plasticdeformation, or other movement), which exerts a radially outward forceon the resilient element 203. Other arrangements are possible.

While in this embodiment the bottom sleeve 202 is fixed relative to thecylinder neck 110 (e.g., by threaded engagement of the bottom sleeve 202with the neck 110, by an adhesive, welding, etc.) and the top sleeve 201is movable relative to the cylinder neck 110 and the bottom sleeve 202,other configurations are possible. For example, the top sleeve 201 maybe fixed relative to the neck 110 and the bottom sleeve 202 may bemoveable (e.g., upwardly toward the top surface 112 of the neck 110).Alternately, both the top and bottom sleeves 201, 202 may be moveablerelative to the neck 110 and to each other.

In this illustrative embodiment, the upper portion 210 of the gasket 200does not include an element that is positioned over the top surface 112of the neck 110, but such an element could be provided, e.g., in anarrangement like any of those discussed herein. Such an element may beattached to the upper end of the top sleeve 201, or may be anindependent part positioned over the top surface 112. Also, the upperend of the top sleeve 201 may be arranged to form a face seal (e.g.,with a bottom surface of a receiver opening), or not. Further, the topsleeve 201 may carry a piercing element, whether the piercing element isattached to the top sleeve 201 or not.

In use, the assembled gasket 200 in the form shown in FIG. 15 a may beinserted into a cylinder receiver 10, e.g., a receiver opening 300 thathas a cylindrical shape with straight sidewalls 310, 320 and a flatbottom surface 340. As the top sleeve 201 contacts the bottom surface340 and the cylinder neck 110 and bottom sleeve 202 are further insertedinto the opening 300, the top sleeve 201 moves toward the bottom sleeve202, exerting a force on the resilient element 203. As a result, theresilient element 203 may move radially outwardly and form a gland sealwith the sidewall of the receiver opening. The seal may be maintained byfixing the cylinder and/or the relative positions of the top and bottomsleeves 201, 202, e.g., by having locking elements of the sleeves 201,202 engage each other or fixing the cylinder in place relative to thereceiver 10. Movement of the top and bottom sleeves 201, 202 toward eachother may be limited, e.g., to prevent excessive force from beingapplied to the resilient element 203. In the embodiment of FIG. 15 b,such movement is limited by the hook 201 a contacting a stop at thebottom end of the bottom sleeve 202, although other arrangements arepossible.

To disengage the cylinder 100 from the receiver 10, the sleeves 201, 202may be moved away from each other, allowing the resilient element 203 tomove radially inwardly. In some embodiments, the top sleeve 201 mayinclude a feature that helps retract the resilient element 203 radiallyinwardly and away from the sidewall of the receiver opening 300, e.g.,to disengage the gland seal and release the resilient element from thesidewall. For example, the top sleeve 201 may include an inwardly angledbevel positioned over the resilient element 203 that is arranged toengage with an upper, outer surface of the resilient element 203 andpull the resilient element 203 radially inwardly as the neck 110 ispulled from the opening 300. Again, other arrangements are possible,such as an outer sleeve that slides over the resilient element 203.

Various modifications to the FIGS. 15 a and 15 b embodiment arepossible. For example, a gasket 200 may include a multiple sleeves andresilient elements coupled to a cylinder neck. The sleeves 201, 202 maybe made of any suitable material or combination of materials, such asmetal or plastic. Similarly, the resilient element 203 may be made of,or include a suitable material, such as rubber, neoprene, and others(including those mentioned herein).

While each disclosed embodiment depicts various features that are usefulin sealing cylinder 100 to receiver 10, these features could be usedeither singularly or in combination to achieve various preferred resultsdepending on the given application.

Having thus described several aspects of at least one embodiment of thisinvention, it is to be appreciated various alterations, modifications,and improvements will readily occur to those skilled in the art. Suchalterations, modifications, and improvements are intended to be part ofthis disclosure, and are intended to be within the spirit and scope ofthe invention. Accordingly, the foregoing description and drawings areby way of example only.

1. An assembly including: a compressed gas cylinder having a neck with atop surface around a gas outlet and a side surface extending downwardlyfrom the top surface, the gas cylinder containing a gas under a pressureof 1000 to 3500 psi that is releasable from the cylinder through the gasoutlet; and a gasket attached to the neck of the gas cylinder, thegasket including: an upper portion made of an elastomeric material andincluding a radially extending portion that defines a face and ispositioned on the top surface of the gas cylinder; and a lower portionhaving a ring including a rigid material that extends around the neck ofthe gas cylinder, the ring extending over a part of the side surface ofthe neck below the top surface of the neck and extending above the topsurface of the neck to support portions of the upper portion above thetop surface against extrusion, the face of the upper portion beingexposed and uncovered by the ring, wherein the radially extendingportion of the upper portion is arranged to engage and form a gas-tightseal with the top surface of the gas cylinder to resist gas leakage pastthe seal with a gas exiting the gas outlet at a pressure of 1000 to 3500psi.
 2. The assembly of claim 1, wherein the lower portion includes asidewall portion made of an elastomeric material extending downwardlyfrom the upper portion, and wherein the ring extends around the sidewallportion.
 3. The assembly of claim 1, wherein the lower portion includesa continuous sidewall portion arranged to extend around the side surfaceof the neck of the cylinder and to form a seal with the side surface. 4.The assembly of claim 1, wherein the upper portion includes an upperopening near a center of the upper portion arranged for positioning overthe gas outlet.
 5. The assembly of claim 4, wherein the upper portion atthe opening is arranged to engage with and make a seal with a piercingelement used to pierce the gas outlet.
 6. The assembly of claim 5,wherein the upper portion at the opening is arranged to form a glandseal with the piercing element.
 7. The assembly of claim 1, wherein theupper portion includes a torus or toroidally-shaped element.
 8. Theassembly of claim 1, wherein the upper portion includes one or moresurface features on a face of the upper surface.
 9. The assembly ofclaim 8, wherein the one or more surface features includes one or morebumps, ridges, grooves, or rings.
 10. The assembly of claim 1, whereinthe lower portion is attached to and extends downwardly from an outerperiphery of the upper portion.
 11. The assembly of claim 1, wherein thelower portion has a cylindrical shell shape or a frustoconical shape.12. The assembly of claim 1, wherein the upper and lower portionstogether form a cup-shaped interior space arranged to receive a part ofthe neck of the cylinder.
 13. The assembly of claim 12, wherein thecup-shaped interior space is tapered to have a smaller size near theupper portion than near a bottom end of the lower portion.
 14. Theassembly of claim 1, wherein the ring is molded with the upper portionand forms part of a sidewall of the lower portion.